DE1449802A1 - Device for recording binary coded information characters displayed in parallel - Google Patents

Description

IBM Germany Internationale Büro-Maschinen Geselhthafi mbH

New registration documents

■ 144S802

Boeblingen, July 23, 1968 ka-sr

Anirielder: International Business Machines

Corporation, Armonk, N.Y.10,504

Official file number: P 14 49 802.3 (J 27 204 IXc / 21a)

File of the applicant: Docket 7627

Device for recording binary coded information characters displayed in parallel.

The invention relates to a device for recording parallel displayed, binary coded information characters, their place values in the tracks of a recording medium are represented by markings of constant and changing polarity of the recording medium.

It is known to record information gauges in the tracks of a magnetic recording medium by means of binary signals in such a way that a signal of positive polarity represents the binary value ¹¹ L "and a signal of negative polarity represents the binary value" O ". This type of magnetic recording is known under the name "Back-to-O" method, because after each representation of a binary value the magnetization of the recording medium is returned to the initial state.

To increase the recording density, it is also known to use only one of the two Binary values can be represented by changing the polarity of the magnetization of the recording medium, while the other binary value is constant Polarity of the magnetization of the record carrier is expressed.

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Such a magnetization pattern is recorded by controlling clock signals, by means of which the changes in the polarity of the magnetization are recorded at predetermined time intervals. The pattern of magnetization is scanned by clock signals of the same frequency, the binary value ¹¹ L "being sampled when a 0 crossing of the magnetization pattern, ie a change in polarity occurs simultaneously with the clock signal. If, on the other hand, a clock signal is present without a change in polarity, the result is the sensing of a binary value "θ". Such a method is known as the "do not go back to 0." This method can indeed achieve a very high recording density However, there is a disadvantage that polarity does not change in a large area of the recording pattern when a large number of binary values "θ" are recorded in succession Components are very high, so a special effort is required for read / write -Amplifiers and the magnetic heads so that the signals can be recorded and sensed in a natural way.

The so-called phase recording method avoids high proportions of direct current and low frequency components in the signal shape. In this method, a binary value ^ir L ^{M is recorded} by a positive change, ie a change in magnetization from negative to positive polarity, and the binary value "θ" is recorded by a negative change, ie a change from positive to negative polarity of magnetization. In this method, however, the recording density is not as high as in the "not-back-to-O ^11" method, because it is necessary to bring the polarity of the magnetization to the correct starting position by changing the magnetization before a certain binary value is represented.

The devices of known type are according to the invention thereby; arierbessert, leave at least each information symbol in a track of the recording medium Assigned to iwei Märfcierungs places arranged one behind the other in the lane direction are, and that at least one of the marking points a change of polarity vorgesene'ii is.

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The measure mentioned achieves that on the one hand a high proportion of the direct current and low frequency components in the waveform is avoided, but that on the other hand a high density of the recording can be achieved by this method.

An exemplary embodiment is explained in more detail with the aid of the figures explained.

Fig. 1 shows an overall view of the device. Binärcodier th information characters are üb ^r * r arel the cannula icr place values b 'j, b ₂ and b, the Binlir-triplicity-Codev / andlor 1j; fed. At the output of this code converter, ternary-coded information characters appear, which are recorded in the two tracks T ₁ and T _{2 of} the magnetic tape 11 via the write device 17. The signals from these two tracks are sensed and fed to the Ternar-Binary Couev / andler 21 via the sense amplifier 19. At the output of this Codev / andlor, binary coded information characters appear on the three channels of the place values b ^, bg and b ,, which can be evaluated by connected devices.

The in Flg. Binary ternary code converter 13 shown in FIG. 1 is shown in FIG. 2A. The signals of the binary-coded Informationsiiciohent fed to the lines b *, b _o un.i b, are converted into four output signals by the AND, OR and inverter trainings of the converter 13. These appear on the lines T1A, T1B, Τ2Λ and T2B in the form of a binary-coded information character. Binary signals result on lines Τ1Λ, T1B, T2A and T2B, each of which is combined in groups of zv / ei binary values. One group of binary values is represented on lines T1A and T1B. The other group of the binary width is created on lines Τ2Λ and T2B. The ternary-coded information characters are represented by suitable combinations of these binary values.The conversion is explained in more detail using the table shown in FIG.

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Which binary-coded information characters of the digits b1, b2 and hj> internal coded information characters of digits a1 and a2 are converted. A binary-coded information character is converted into a corresponding four-digit binary value which is assigned to the lines T1A, T1B, T2A and T2B. In each case zeri of these place values form the coding for one of the three ternary values G, 1 and 2. From the table it is evident that the correlation of the two binary values 0, 1 results in the ternary value 0, the combination of the two binary values -Values 1.0 represent the ternary value 1 and the combination of the two binary values 1 represent the ternary value 2. The right column of the table shows the ternary-coded information characters of the two place values a1 and a2. A maximum of eight different possible combinations can be achieved using binary-coded three-digit information characters, while two-digit ternary-coded information characters can be used to represent a maximum of nine different combinations. These signals are recorded one after the other in the recording track T1 of the magnetic tape 11 In der 'Welse that the value T1A in the first half and the value T1B in the second half of a character interval are written Assigned to T2A and T2B. These two signals are recorded one after the other in the track T2 of the magnetic tape 11 that the signal T2A is written in the first half and the signal T2B in the second half of a drawing interval.

The middle part of the table shown in Fig. 2 shows that two binary signals are assigned to each ternary value, at least one of which is expressed by the binary value t

Coding enables a signal form on the recording medium in which there is a frequent change in the polarity of the magnetization, regardless of whether a greater number of the same or

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different ternary values can be recorded one after the other. This avoids a high proportion of DC and low-frequency components in the signal shape. The binary coded information characters are converted according to this principle into ternary-coded information symbols for the purpose of recording. as well there is the possibility to use the ternary-coded Information characters back into binary-coded information areas to convert. Using FIG. 3, it was explained how three-digit binary-coded information characters are ternary-coded into two-digit Information signs can be implemented. By adapting the code converter accordingly, binary-coded information characters can also be used higher number of digits can be converted into ternary-coded information characters. In the case of such conversions, the Task of expressing a ternary value by binary signals of each of which can be represented by changing from one polarity to another of the recording medium.

FIG. 2B shows the essential details of the write amplifier 17 shown in FIG is only the output signals T1A and T1B of the binary-ternar converter 13 assigned. These signals cause the markings to be recorded in track T1 of the magnetic tape 11. The output signalsc T2A and T2B of the binary-ternary converter 13 become the recording track T2 of the magnetic tape 11 is fed. The write amplifier required for this is not shown in FIG. 1. It has the same design as the write amplifier 17 shown in FIG. 2B.

The signals derived on lines T1A and T1B are fed to AND circuits 51 and 33 as shown in FIG. 2A. These AND circuits are keyed by signals from the two clock generators S1 and S2. These signals from the two clock generators have a phase shift, namely the clock signals of the S1 generator occur at the Α times and the signals from the clock generator S2 occur at the B times. These cycle times are shown in FIGS. 4b and kc. A signal 81 (A) appears on the output line of the AND circuit when a clock signal is present at the inputs of the AND circuit and a binary one signal is present on the line T1A. Likewise, a appears at the output of the AND circuit 33

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S2 (B) Signal when a clock signal is present at the inputs of the AND circuit 33 and a binary one signal is present on the line T13. The two SignaliULgen S1 (A) and S2 (B) combine at the output of the OR circuit 35 to form the sum pulse sequence S1, 2 (A, B), the signals of which control the magnetic head 41 via the binary trigger 39. The magnetic head 41 causes signals in the recording track T1, which are in the Pig. 4B. Corresponding waveforms are recorded in the track T2 by a corresponding writing amplifier, not shown, the waveforms of which are shown in FIG. 4C. In this way, 11 magnetization patterns are recorded in the two tracks T1 and T2 of the magnetic tape, which are represented by magnetizations of alternating polarity in accordance with the "do not return to 0" method.

According to the illustration according to FIG. 1, the two recording tracks T1 and T2 are sensed, the ones being sensed in the track T1 Signals are fed to the ternary-to-binary converter 21 via the sense amplifier 19. In a corresponding way, those in the track T2 cooled signals via a read amplifier, not shown fed to the input of the ternary-to-binary converter 21. There are therefore binary-coded information characters at the output of the converter 21 of the binary digits b1, b2 and b3 can be derived. Fig. 2C shows one Implementation of the ternary-to-binary converter 21, which consists of inverters and AND and OR circuits. This converter is used to get off the binary-ternary-coded signals T1A, T1B, which come from the track T1 and from the binary-fcernar-coded signals T2A, T2B, which were sensed from the track T2, to form signals which binary-coded information on the output lines b1, b2 and b3 to represent signs.

The functioning of the facility is based on the Sighal sequences that 4A to 4C are illustrated in more detail. Figure 4A shows a binary-coded information symbol with the binary digits b1, b2 and b3. Each of these information signs has a specific one Assigned to time interval. 4B shows the signals T1A and T1B appearing simultaneously at the outputs of the converter 13.

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The binary signals on lines b1 to b3 and T1A, T1B are within a time interval that is assigned to an information symbol, always either by a positive or by one negative voltage value shown.

These signal forms are scanned by during the Α times Signals from the clock generator SI. During the B-SJeIten, the Waveforms sampled by the signals from the clock generator S2. This results in the signal sequences S1 (A) and S2 (B), the can be combined to form a sum pulse train S1, 2 (A, B). In the track T1 of the magnetic tape 11, the T1 signals are recorded. The T1 values (binary) are assigned to these signals. The coding of these binary values results in the al (ternar) digit values the recording track T1. Each of the al-places is assigned to a time interval »in which at least one change the polarity of magnetization takes place.

In the same way as for the track T1, the binary-coded information characters of the positions b1 to b3 the corresponding a2 places of the associated ternary-eroded Information signs can be derived. This derivation of the various waveforms is illustrated by Figure 4C.

The device described shows a method for the display of information signs on recording media which is a recording density in the tracks of the recording medium of 0.79 bits / flux change is achieved. Known devices for the method of phase recording, however, result only a recording density of 0.5 bits / flux change. this means an increase in recording density of approximately £ 60 The device described also has the advantage that when the information characters are scanned, the clock signals are emitted very easily the information signals can be derived. The effort for the representation the clock signals are low because a flow change takes place in each time interval of the information signals.

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Claims (4)

-8- ■) 4493 Q2 P 14 49 802.3 July 23, 1968 ka-sr PATENT CLAIM E 1. E device for recording binary coded images displayed in parallel Information ζ whose position is in the traces of a recording medium are represented by markings of constant and alternating polarity of the recording medium, characterized in that in a track of the recording medium each information character at least two in the track direction arranged one behind the other MarMerungs provide are assigned, and that a change in polarity is provided at at least one of the marking points. 2. Device according to claim 1, characterized in that the number of digits the binary coded information characters shown in parallel to the number of marking points on the recording medium by a code converter is adjusted information signs shown. 3. Device according to claims 1 and 2, characterized in that the binary coded information characters shown in parallel are converted into ternary coded information characters. 4. Device according to claims 1 to 3, characterized in that each place value (a I, a 2} of a binary coded information character the signals T1, A, T 1 B; T 2 A, T 1 B) of two arranged one behind the other Marking points is represented, which are scanned within a character interval in successive time segments (A, B) by clock signals be, and that in at least one of the two MarMerungs represent a change from one to the other polarity of the recording medium is provided. 80981 1/0386 i Cs A-